Multi-zonal roller and method of use thereof

Abstract

The present invention generally relates a multi-zonal and non-circular roller with several different zones along the periphery of the roller's outer surface and more specifically a roller having a non-circular internal area, a non-regular external surface covered by a series of multiple shape and angles designed to include to offer a user different types of resistance and muscle relief, including a point for the management of a myofascial trigger point.

Claims

1. A multi-zonal roller for therapeutic, fitness, and sports enhancement device, comprising: a thin-walled tube with a thickness, a width, and an outside surface; and an external shell of soft polymer with an internal surface in contact with the outside surface of the thin-walled tube, wherein the external shell has a variable thickness defining an outer surface of use for therapeutic, fitness, and sports enhancement by contact with a user body, wherein the variable thickness circumferentially defines a plurality of zones each opposite along the circumference of a tip point; wherein the external shell includes three tip points and the plurality of zones includes three zones each covering approximately 120 degree circumferentially of the roller and wherein each zone is delimited by two of the three tip points; and wherein a first zone is defined by a series of small semi-circular central longitudinal bumps along the width of the roller and flanked by two more longitudinal bumps of identical geometry at a distance along the first zone to create a first flat portion between the small semi-circular central bumps and the flanking bumps.

2. The multi-zonal roller of claim 1, wherein the thin-walled tube is generally oblong.

3. The multi-zonal roller of claim 2, wherein one of the two oblong axis is longer than the other by a ratio of 1.05 to 1.40.

4. The multi-zonal roller of claim 1, wherein a second zone is defined by a series of larger semi-circular central longitudinal bumps along the width of the roller and flanked by two more longitudinal larger bumps of identical geometry as the larger semi-circular central longitudinal bumps at a distance along the second zone to create a second flat portion between the larger semi-circular central longitudinal bumps and the flanking bumps.

5. The multi-zonal roller of claim 4, wherein a third zone is defined by a third flat area with a semi-straight area.

6. The multi-zonal roller of claim 1, wherein at least one of the three tip points includes a semi-rounded point with a flat side on one side leading to one of the three zones and a flat side on the other side leading to another of the three zones.

7. The multi-zonal roller of claim 1, wherein the soft polymer forming the external shell of each of the three zones has a different density.

8. A method of use of a multi-zonal roller for therapeutic, fitness, and sports enhancement device, the method comprising the steps of: selecting a multi-zonal roller comprising of a thin-walled tube with a thickness, a width, and an outside surface, and an external shell of soft polymer with an internal surface in contact with the outside surface of the thin-walled tube, wherein the external shell has a variable thickness defining an outer surface of use for therapeutic, fitness, and sports enhancement by contact with a user body, wherein the variable thickness circumferentially defines a plurality of zones each opposite along the circumference of a tip point, wherein the external shell includes three tip points and the plurality of zones includes three zones each covering approximately 120 degree circumferentially of the roller and wherein the each zone is delimited by two of the three tip points, wherein a first zone is defined by a series of small semi-circular central longitudinal bumps along the width of the roller and flanked by two more longitudinal bumps of identical geometry at a distance along the first zone to create a first flat portion between the small semi-circular central bumps and the flanking bumps; placing on the ground at least one of the tip points; contacting a portion of a user's body against one of the plurality of zones at the opposite side of the roller; and pivoting around the tip point the roller by moving the user's body as to allow the zone to contact the user's body.

9. The method of claim 8, wherein the thin-walled tube is generally oblong.

10. The method of claim 9, wherein the device includes structure where one of the two oblong axis is longer than the other by a ratio of 1.05 to 1.40.

11. The multi-zonal roller of claim 8, wherein a second zone is defined by a series of larger semi-circular central longitudinal bumps along the width of the roller and flanked by two more longitudinal larger bumps of identical geometry as the larger semi-circular central longitudinal bumps at a distance along the second zone to create a second flat portion between the larger semi-circular central longitudinal bumps and the flanking bumps.

12. The method of claim 11, wherein a third zone is defined by a third flat area with a semi-straight area.

13. The method of claim 12, wherein at least one of the three tip points includes a semi-rounded point with a flat side on one side leading to one of the three zones and a flat side on the other side leading to another of the three zones.

14. The method of claim 8, wherein the soft polymer forming the external shell of each of the three zones has a different density.

Description

BRIEF DESCRIPTION OF DRAWINGS

(1) FIG. 1 an isometric view of the roller according to an embodiment of the present disclosure.

(2) FIG. 2 is a side view along axis X-X′ of the roller as shown at FIG. 1 according to an embodiment of the present disclosure.

(3) FIG. 3 is a front view of the roller as shown at FIG. 1 according to an embodiment of the present disclosure.

(4) FIG. 4 is a back view of the roller as shown at FIG. 1 according to an embodiment of the present disclosure.

(5) FIG. 5 is an isometric view showing Zone II in the foreground of a short width version of the roller as shown at FIG. 1 according to a second embodiment of the present disclosure.

(6) FIG. 6 is an isometric view of the roller as shown at FIG. 5 with Zone I in the foreground according to the second embodiment of the present disclosure.

(7) FIG. 7 is a cut view along axis A-A as shown at FIG. 5 according to an embodiment of the present disclosure.

(8) FIG. 8 is a cut view along axis B-B of the external shell as shown at FIG. 5 according to an embodiment of the present disclosure.

DETAILED DESCRIPTION

(9) The current invention is one described as part of the field of health and rehabilitation of muscles linked often with exercise and/or other trauma. The description shows and uses terminology linked with products generally found in modern gyms. But while one type of technology is described using one vehicular, one of ordinary skill in the art will understand this technology can also be use in medical centers and rehabilitation centers to help patients return to full health or to help alleviate pain.

(10) FIG. 1, shows generally an isometric side view of Roller 100. While the shape is generally irregular and explained with greater clarity below, one of ordinary skill can generally use a three-dimensional coordinate system that includes the width (W) of the Roller 100, a radius (R) that generally defines the distance from a central axis (X-X′) as illustrated. Finally, to described with great precision the exact location along the circumference (internal or external) of the Roller 100, the inventor uses an Angle (φ) having as a reference the plan view (Y-Y′) shown at FIG. 1.

(11) As shown the Roller 100 is of a width (W) sufficient for a portion of the body to be placed thereon, as shown the Roller 100 be at least 10-24 inches. While one of ordinary skill in the art observes a Roller 100 with a width as shown, what is contemplated is any length which allows for a portion of the human body to rest against the Roller 100, from one sufficient to only house an arm to one of sufficient length to house the thorax of an individual. In an alternate embodiment, the width is only 4-7 inches when designed for individual portions of the human body like an arm or a leg instead of the torso.

(12) The Roller 100 is illustrated using a variable internal radius (RI) and a variable external radius (RX) which as shown while variable along the Angle (φ), does not change along the width (W). In one anticipated mode of fabrication, the shape is extruded using a simple die/push cast. The Roller 100, when in need of skeletal support strength may include an inner tube 2 made of a rigid yet somewhat pliable polymer which is designed to help support and give structure to the Roller 100. In the preferred embodiment, the tube 2 is glued onto the external shell 3. In another embodiment, the tube 2 is slipped inside by expanding the external shell 3 temporarily and assembled simply by allowing the external shell 3 to contract and return to form. Both tube 2 and external shell 3 can be made of several known plastics, for example, injected molded plastics. In one embodiment an EVA-TPR (Ethylene Vinyl Acetate copolymer/ThermoPlastic Rubber or Elastomer). In another embodiment, the tube 2 is made of Polypropylene of 3 mm think and includes small finds to help give traction between the tube 2 and the external shell 3 on the outside surface.

(13) The inner tube 2 can be made of thermoplastic for example made of acrylic, ABS, Nylon, PLA, Polybenzimidazole, Polycarbonate, Polyether sulfone, Polyoxymethylene, Polyetherether ketone, Polyetherimide, Polyvinyl chloride, Teflon, Polyvinylidene fluoride, Polypropylene or the like. As shown at FIG. 2 with greater clarity, the inner tube 2 can have a regular thickness (t) along its full circumference even if the internal radius of the inner tube surface 3 can be irregular in its distance to the axis X-X′. The Roller 100 as shown at FIG. 2 shows the product in one orientation where the vertical distance 5 of the inner tube 2 is longer than the horizontal distance 6 of the inner tube 2. In one embodiment, the ratio of the vertical distance over the horizontal distance is in the range of 1.05 to 1.15. In another embodiment, the ratio can reach 1.15 to 1.40. What is not shown bot also contemplated is where ¾ of the inner tube 2 is circular and only the upper third is expanded upward. In that case, the ratios can be lowered to 1.025 to 1.075. In one embodiment, the thickness of the tube (t) is a range between 2-5 mm. In another embodiment, the tube thickness can be between ⅛.sup.th to ¼.sup.th of an inch under the English unit model. While certain thicknesses have been given, what is contemplated is the use of any tube having sufficient rigidity to meet its purpose of allowing the outer external shell 3 to offer its purpose of support to a user. In one embodiment, a surface protective flexible layer 4 can be added to the outside of the external shell 3 to offer the roller additional properties such as being germ resistant or having a different surface roughness.

(14) Surrounding the inner tube 2 is a compressible external shell 3 thickness of variable radial thickness (T) shown as T1, T2, and T3 on FIG. 7 around the Angle (φ) shown φ1, φ2, φ3 as from the central axis X-X′. Returning to FIG. 2, generally speaking three ‘zones’ named Zone I 200, Zone II 300, and Zone III 400, are offered for use to users. Each zone takes generally about 120 degree from the axis X′X′ creating three zones of similar size. As shown at FIG. 6, at the apogee (i.e. the other side) of the central region of each Zone I, II, and III, is a Tip Point shown at TP1 500, TP2 600, and TP3 700. TP1 is place at the apogee of Zone I, TP2 is illustrated at the apogee of Zone II, and TP3 is shown as the apogee of Zone III.

(15) The polymeric foam of the external shell 3 also known as a foam can be made of a polymer having internal bubbles of air or air structure to give the polymer a soft feeling to the touch and in some case allowing the polymer to greatly deform and bounce back slowly with time (a couple of seconds). General foams used for contact with the human skin include foams able to deform and return after pressure has been stopped to their original form. For example, ethylene-vynil acetate (EVA) foam, low-density polyethylene (LPDE) foam, nitrile rubber (NBR) foam, polychloroprene foam, polyimide foam, polypropylene (PP) foam, polystyrene (PS) foam, Styrofoam, polyurethane (PU) foam, polyethylene foam (PEF), polyvinyl chloride (PVC) foam or silicone foam. Foam is generally defined by both a density (weight per unit of volume). For most polyfoams, a low-density range is less than 1.5 PCF. The medium-density range is from 1.5 to 1.7 PCF and the high-density range is more than 1.7 PCF. Firmness is measure on a scale of 1 to 10 where 1 is the softest and 10 is the firmest and firmness. One of ordinary skill will understand the possibilities and possible variations linked with alternating and changing the density of the foam. For example, the shell 3 could be made of different zones having different density. While the current contemplated embodiment includes a single shell with uniform density foam, one may understand for example that Zone 3 400 and TP3 600 designed for a lower level of compression and a greater rigidity. As described above, in cases where different density segments are used, may be manufactured using injection or assembly via thermal movement but may also be manufactured using glued EVA sheets layered over the tube 2 then cured using a heat tunnel. Such layers would be selected to modulate and change the effective total density of the segment and could be compression molded or injection molded. Other methods of manufacturing include the use of the tube 2 with a flat layer of EVA followed by a compression molding to alter the outer use diameter. Thermoplastics with memory also may be used.

(16) Description of Zones I, II, and III and Tip Points 1, 2, and 3

(17) As shown at FIG. 6, Zone I 200 is made of a series of small semi-circular bumps 50 with a radius RI 51 around 2-4 mm. The distance between two subsequent bumps 50a, 50b, 50c is about three times RI 51 or about 6-12 mm. As shown, eight bumps 50 are place in the central portion of Zone I 200 and are flanked by two more bumps 52a, 52b to define a flat portion 53 between the bumps 50 and the bumps 52. To better view the flatness of flat portion 53, this is illustrated at FIG. 2. Returning to FIG. 6, the goal of the side bumps 52a is to create a flat area formed by 50a and 52a with the distance 53. When Zone I 200 is put upward for use against a portion of the human body, the other side's TP1 Tip Point 500 must be placed in equilibrium against the floor. A person will rock the leg over the bumps 50 back and forth. When the product is then used with the TP1 Tip Point 500 upwards and the other side Zone I 200 against the ground, the movement of the leg against the TP1 Tip Point 500 will feel by a balancing movement the bumps 50. The two side bumps 52a will then provide a guide to help a user delineate where Zone I 200 starts and stops. Zone I 200 as shown includes a series of 8 central bumps 50 and two side bumps 52.

(18) Zone II 300 is rather analogous to Zone I 200 in that it is made of somewhat larger series of semi-circular bumps 60 with a radius RII of 4-8 mm. The same way as Zone I 200, distance between two subsequent bumps 60a, 60b, 60c is about three times RII 61 or about 18-36 mm. As shown, three bumps 60 are place in the central portion of Zone II 300 and are flanked by two more bumps 62a, 62b to define a flat portion 63 between the bumps 60 and the bumps 62. The goal of the side bumps 62a is to create a flat area formed by 60a and 62a with the distance 63. When Zone II 300 is put upward for use against a portion of the human body, the other side's TP2 Tip Point 600 must be placed in equilibrium against the floor. A person will rock the leg over the bumps 60 back and forth. When the product is then used with the TP2 Tip Point 600 upwards and the other side Zone II 300 against the ground, the movement of the leg against the TP2 Tip Point 600 will feel by a balancing movement the bumps 60. The two side bumps 62a will then provide a guide to help a user delineate where Zone II 300 starts and stops. Zone II 300 as shown includes a series of 3 central bumps 60 and two side bumps 62.

(19) Zone III 400 is completely different in that it is mostly flat 70 and includes a semi-straight area 71 once again to allow the Roller 100 to reset with stability on the ground with TP3 Tip Point 600 in the highest of position. As shown, Zone III 400 is the thinnest of the three zones Zone I 200, Zone II 300 and Zone III 400. The thin layer as shown is around 6-12 mm thick or about 2-3 times the thickness of the tube 2. Returning to the description of the TP3 Tip Point 600, as shown the tip includes a semi-rounded point 75 with a flat side 76 leading onto Zone I 200 and a slightly curved side 77 leading into Zone II 300. As shown, the thickness of Tip Point 600 is 5-10 times the thickness of the thickness of Zone III 400.

(20) Written simply, the invention is a multi-zonal roller 100 for therapeutic, fitness, and sports enhancement device. It comprises a thin-walled tube 2 with a thickness (t), a width (W), and an outside surface (not numbered) and an external shell 3 of soft polymer with an internal surface as shown at FIG. 1 in contact with the outside surface of the thin-walled tube 2.

(21) The external shell 3 as shown has a variable thickness T1, T2, and T3 as shown at FIG. 7, defining an outer surface of use for therapeutic, fitness, and sports enhancement by contact with a user body (not shown). The variable thickness circumferentially defines a plurality of use zones shown at FIG. 2 as Zone I 200, Zone II 300, and Zone III 400 each opposite along the circumference of a tip point shown as TP1 500, TP2 600, and TP3 700 at FIG. 6.

(22) The thin-walled (t) tube 2 is generally oblong as shown at FIG. 2. One of the two oblong axis 5, 6 may be longer than the other by a ratio of 1.05 to 1.40. The external shell includes three tip points TP1 500, TP2 600, TP3 700 and the plurality of zones Zone I 200, Zone II 300, and Zone III 400 include three zones each covering approximately 120 degree circumferentially of the roller and wherein the each zone is delimited by two of the three tip points as shown at FIG. 2.

(23) The first zone (Zone I 200) is defined by a series of small semi-circular central longitudinal bumps 50a, 50b, 50c, . . . . along the width (W) of the roller 100 and flanked by two more longitudinal bumps 52a, 52b of identical geometry at a distance along the first zone to create a first flat portion between the small semi-circular central bumps and the flanking bumps 53. The second zone (Zone II 300) is defined by a series of larger semi-circular central longitudinal bumps 60a, 60b, 60c, along the width (W) of the roller 100 and flanked by two more longitudinal larger bumps 62a, 62b as shown at FIG. 6 of identical geometry as the larger semi-circular central longitudinal bumps at a distance along the second zone 300 to create a second flat portion 63 between the larger semi-circular central longitudinal bumps 60 and the flanking bumps 62.

(24) As shown at FIG. 6, a third zone (Zone III 400) is defined by a third flat area 70 with a semi-straight area 71. At least one of the three tip points TP3 700 includes a semi-rounded point 75 as shown at FIG. 5 with a flat side 76 on one side leading to one of the three zones and a flat side 77 on the other side leading to another of the three zones. The soft polymer forming the external shell 3 of each of the three zones (Zone I, Zone II, and Zone III) may have a different density (not illustrated).

(25) What is also contemplated is method of use of a multi-zonal roller 100 for therapeutic, fitness, and sports enhancement device, the method comprising the steps of: selecting a multi-zonal roller as described above, placing on the ground at least one of the tip points; contacting a portion of a user's body against one of the zone at the opposite side of the roller, and pivoting around the tip point the roller by moving the user's body as to allow the zone to contact the user's body.

(26) Exemplary embodiments are described and shown above. It is, however, expressly noted that these exemplary embodiments are not limiting, but rather the intention is that additions and modifications to what is expressly described herein also are included within the scope of the present implementation. Moreover, it is to be understood that the features of the various embodiments described herein are not mutually exclusive and can exist in various combinations and permutations, even if such combinations or permutations are not made express herein, without departing from the spirit and scope of the present invention.

(27) In one contemplated embodiment, the assembly process of the tube 2 and the external shell 3 can include the use of a high temperature and/or compressed air to help the foam expand during the assembly and return to tighten with the surface when cold. The use of the outside diameter fins (not shown) on the outside diameter of the tube 2 helps create a greater amount of friction. In the event thermal constriction is used to close the gap between the tube 2 and the external shell 3, the use of any adhesive may not be required.

(28) What is also contemplated is the use of vibration technology inside of the tube 2, a smaller travel version, the use of a thermal element to create hot and cold areas (e.g. via slide in pads or low current and rechargeable batteries. Also, the use of end caps or other bags and carry items for the movement of the product is contemplated.

(29) Since certain changes may be made without departing from the scope of the present implementation, it is intended that all matter contained in the above description or shown in the accompanying drawings be interpreted as illustrative and not in a literal sense. Practitioners of the art will realize that the sequence of steps and architectures depicted in the figures may be altered without departing from the scope of the present implementation and that the illustrations contained herein are singular exemplar examples of a multitude of possible depictions of the present implementations.